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Alvanchi, A and JavadiAghdam, S (2019) Job site weather index: an indicator for open environment construction projects. Construction Innovation , 19(01), 110–24.

Azadeh, A, Kalantari, M, Ahmadi, G and Eslami, H (2019) A flexible genetic algorithm-fuzzy regression approach for forecasting. Construction Innovation , 19(01), 71–88.

Janné, M and Fredriksson, A (2019) Construction logistics governing guidelines in urban development projects. Construction Innovation, 19(01), 89–109.

Majava, J, Haapasalo, H and Aaltonen, K (2019) Elaborating factors affecting visual control in a big room. Construction Innovation , 19(01), 34–47.

Saini, M, Arif, M and Kulonda, D J (2019) Challenges to transferring and sharing of tacit knowledge within a construction supply chain. Construction Innovation, 19(01), 15–33.

Shoar, S, Nasirzadeh, F and Zarandi, H R (2019) Quantitative assessment of risks on construction projects using fault tree analysis with hybrid uncertainties. Construction Innovation, 19(01), 48–70.

  • Type: Journal Article
  • Keywords: Innovation; Project management; Management; Construction management; Risk assessment/risk management; Computational and numerical techniques;
  • ISBN/ISSN: 1471-4175
  • URL: https://doi.org/10.1108/CI-07-2018-0057
  • Abstract:
    The purpose of this paper is to present a fault tree (FT)-based approach for quantitative risk analysis in the construction industry that can take into account both objective and subjective uncertainties. Design/methodology/approach In this research, the identified basic events (BEs) are first categorized based on the availability of historical data into probabilistic and possibilistic. The probabilistic and possibilistic events are represented by probability distributions and fuzzy numbers, respectively. Hybrid uncertainty analysis is then performed through a combination of Monte Carlo simulation and fuzzy set theory. The probability of occurrence of the top event is finally calculated using the proposed FT-based hybrid uncertainty analysis method. Findings The efficiency of the proposed method is demonstrated by implementing in a real steel structure project. A quantitative risk assessment is performed for weld cracks, taking into account of both types of uncertainties. An importance analysis is finally performed to evaluate the contribution of each BE to the probability of occurrence of weld cracks and adopt appropriate response strategies. Research limitations/implications In this research, the impact of objective (aleatory) dependence between the occurrences of different BEs and subjective (epistemic) dependence between estimates of the epistemically uncertain probabilities of some BEs are not considered. Moreover, there exist limitations to the application of fuzzy set rules, which were used for aggregating experts’ opinions and ranking purposes of the BEs in the FT model. These limitations can be investigated through further research. Originality/value It is believed that the proposed hybrid uncertainty analysis method presents a robust and powerful tool for quantitative risk analysis, as both types of uncertainties are taken into account appropriately.

Sundling, R, Blomsterberg, & and Landin, A (2019) Enabling energy-efficient renovation: the case of vertical extension to buildings. Construction Innovation, 19(01), 2–14.